Huh?

So you've been reading about all the benefits of this "mindfulness" thing and you want to give it a try. You do some research and learn it requires "meditation", "introspection" and other kinds of tedious woo. Who has time for that? It's {current_year} for christ's sake! I don't want a tiny tray of rocks and sand on my desk to rake around. Surely there's some turn-key solution to this problem already.

That's what this project is for. Outsource responsibility for an ordered mind to make more time for the important things, like computer games. And croissants.

Oh

This project (will contain/contains) all the knowledge you will need to build your own sand drawing robot. Heavily inspired by the likes of Sandsara and Sisyphus. It's a robot that moves a ball around in a bed of sand to draw cool patterns. The patterns can be updated via wifi, and it can cycle through them, you can create your own, etc, etc. This project is open source, cheap, and hopefully as easy as possible to build.

Building it

Skills required

This isn't a Lego set. You'll need to have access to the following skills:

• Basic woodworking,
• Intermediate soldering,
• Following technical instructions,
• Drilling a hole sideways through steel rod,
• Recovering from setbacks.

I'll do my best to make the instructions as comprehensive and comphrehensible as I can. I appreciate any and all feedback.

Videos

Playlist on Youtube. Maybe worth watching.

Build logs

For now the build logs are on my wiki. Over time they'll morph into actual instructions and end up in this repo.

Bill of materials

None of these parts are particularly hard to find. Check ebay and whatnot. Try to buy local if you can. It's hard to guess how much it will all cost in total, but I've tried to design everything to be as economical as possible. Excluding the housing I would (very roughly) estimate the BoM to come out to around AUD$200. The housing could be as cheap as AUD$50 (Melamine board, polycarbonate) or as expensive as you want, with lacquered hardwood and tempered glass.

Mechanical

Item	Type	Count	Note
Printed parts	Various	8?	Basic parts. Small and easy to print.
Stepper pulley	GT2-20, 12.35mm high	2	My steppers had pulleys from the factory.
Belt	S2M belt 120mm	2	S2M ≈ GT2.
Belt	S2M belt 278mm	1
Shaft 1	8mm x 90mm	1	Mild steel is easier to cross-drill than stainless.
Shaft 2	8mm x 33mm	1
Bearing	608	6	Cheap skate bearings are fine.
Washers	8mm ID, 15.7mm OD	5	OD not critical, but it must not rub on outer race of bearings.
Washers	3mm ID, 6.8mm OD	12
Bolts	M3x12mm	8	I used all 20mm and cut them to length.
Bolts	M3x20mm	2
Nylock nuts	M3	2	Nylock not critical.
Pins	2mm diameter	5	Roll pins would be best, I used nails. +1 extra for pinning shaft 1 into the bearings.
Magnets	12mm diameter, 2mm high neodymium	2	Dimensions not critical.
Cable ties	200mm x 4.6mm Nylon	2	Dimensions not critical.

Electrical

Item	Type	Count	Note
Microcontroller	ESP-WROOM-32D	1	Wifi and bluetooth built-in
Stepper motor	NEMA-17	2	200 steps/revolution, around 40mm long, at least 30 N.cm of holding torque. It's not critical, really.
Stepper driver	Pololu pinout	2	A4988, DRV8825 or TMC2100 in increasing order of preference
PCB	Custom made	1	The design is here. It's easier and cheaper to have one made than you might imagine.
Optoswitch	??	2	Used for detecting arm position. Current design uses slotted optoswitches, but reflective might be better? Watch this space.
PSU	12v DC 1A	1	A wall wart should be fine.
Stepper driver socket	16x1 2.54mm female	2	https://au.rs-online.com/web/p/pcb-sockets/2304893/
Stepper motor socket	4x1 3.5mm	2	https://au.rs-online.com/web/p/pcb-headers/8971039/
Stepper motor plug	4x1 3.5mm	2	https://au.rs-online.com/web/p/pcb-terminal-blocks/8971004/
Optoswitch socket	3x1 3.5mm	2	https://au.rs-online.com/web/p/pcb-headers/8971020/
Optoswitch plug	3x1 3.5mm	2	https://au.rs-online.com/web/p/pcb-terminal-blocks/8971001/
Power socket	2x1 3.5mm	1	https://au.rs-online.com/web/p/pcb-headers/8971026/
Power plug	2x1 3.5mm	1	https://au.rs-online.com/web/p/pcb-terminal-blocks/8970998/
Buttons	6mm	2	https://au.rs-online.com/web/p/tactile-switches/1359534/
UART Header	3x1 2.54mm male	1	https://au.rs-online.com/web/p/pcb-headers/8967364/
12VDC Barrel socket	2.1mm pin	1	https://au.rs-online.com/web/p/dc-power-sockets/0448370/

Enclosure

Item	Type	Count	Note
Base	Wooood?	1	Holds the steppers and circuitry.
Top	Wooood?	1	Any convex polygon should work.
Bed	Glass?	1
Lid	Glass	1
Sand	Sand	31378908	< 100 μm grains, dry.

Communication

The ESP-WROOM-32 has wifi and BLE built in. Currently the robot connects to a wifi network, then an MQTT server, to receive commands. Bluetooth should also be possible in the future.

MQTT Topics

There are a few topics that the robot listens to. Each topic starts with {secrets.mqtt_root}/sand_drawing/. I suggest you publish patterns/generators with the retain bit so the robot starts up and then begins that pattern.

Topic	Example payload	Description
pattern	G28 X,G28 Y,G1 X0 Y175,G1 X123 Y123,G1 X175 Y0,J0 2	Starts drawing the pattern defined by the GCODE in the payload.
generator	Here	Starts drawing the pattern defined by the generator in the payload. See below for details on generators.
save_generator	1.pat {generator string}	Saves the generator to a file in the robot's flash storage. The file extension must be .pat. A blank string will erase the generator.
run_generator	1.pat	Starts drawing the previously saved generators.
delete_generator	1.pat	Deletes a generator saved to the robot.
list_generators	N/A	Publishes a list of filenames to generator_list topic.
shuffle_generators	3600	Randomly picks a saved generator and starts drawing it. Optionally provide a number of seconds before choosing another random generator

Configuration

There are some files you'll need to edit before your robot will work for you, probably. #TODO populate this section.

Pattern definition

There are currently two ways to design patterns for the robot.

GCODEs

This is a sequence of coordinates that define the path of the ball, as well as changing modes and looping. The following GCODES are currently supported. GCODES are separated by a comma.

Name	GCODE	Example	Description
Home axis	G28	G28 X,G28 Y,	Home either the X or Y axis. Any command that needs an absolute position reference will fail unless both axes have been homed first.
Move	G1	G1 X10 Y50 S100,	Go to the X and Y coordinates specified at 100mm/s. Currently the speed field is ignored. The G1 movement mode carefully tracks every step and should be perfectly accurate if your steppers do not slip.
Fast move	G0	G0 X10 Y50 S100,	Same as G1 however the step signal square wave is generated using PWM so some resolution is lost. At time of writing it is not well-supported. It's really fast though.
Coordinate mode	G16	G16 0,	This setting is used to control the interpretation of the X and Y parameters in the G0 and G1 commands. 0: Raw speed, 1: Raw angle, 2: Cartesian (Default), 3: Polar (unimplemented)
Jump	J0	J0 3,	This jumps to the specified line in the GCODE-defined pattern. Used for creating loops.
Absolute coordinate mode	G90	G90	Puts the robot into absolute movement mode. Coordinates in G0/G1 commands are interpreted as absolute position references. (Default)
Relative coordinate mode	G91	G91	Puts the robot into relative movement mode. Coordinates in G0/G1 commands are interpreted as movement vectors from the previous position.

Generators

You can define a pattern using a python generator function. Examples here. This is probably the best option for non-trivial patterns.

Tread lightly

Keep the target hardware in mind when writing generators. It's very resource-constrained. Try to limit RAM usage, and think hard before importing anything. There are some helper functions and constants in-scope that you can use.